Bookkeeping machine



Oct. 17, 1939. H. NEUEITER r-:r A1. 2,176,146

BOOKKEEPING MACH INE Oct 17, 1939. H. NEUEITER ET AL BOOKKEEPING MACHINE Filed June 8, 1954 l5 Sheets-Sheet 2 FIG.3

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BDOKKEEPING MACHINE Filed June 8. 1934 l5 Sheets-Sheet 3 Inventor;

WM Maw Oct. 17, 1939. H. NEUEITER Er Ax. 2,176,146

BOOKKEEPING MACHINE Filed June 8. 1954 15 Sheets-Sheet 4 Oct. 17, 1939. H. NEUEITER Er AL 2,176,146

BOOKKEEPING MACHINE Filed June B, 1954 15 Sheets-Sheet 5 Snnentorg AUX/56 W MOL/ Oct. 17, 1939. H. Neus-:ITER ET AL 2,176,146

BOOKKEEPING MACHINE Filed June 8, 1934 l5 Sheets-Sheet 6 1 a F|G.1O g a I nlm l.

Oct. 17, 1939. H. NEuErrER Er Al.

BOOKKEEPING MACHINE Filed June 8, 1954 15 Sheets-Sheet 7 FIG. 11

Jmnmtorf 67 z' torneg Oct. 17, 1939. H. NEUEITER Er AL 2,176,146

BOOK KEEPING MACHINE Filed June 8, 1934 l5 Sheets-Sheetl 8 Oct. 17, 1939. H. NEur-:ITER Er AL 2,176,146

BOOKKEEPING MACHINE Filed June B. 1934 15 Sheets-Sheet 9 Oct. 17, 1939. H. NEUEITER Er A1.

BOOKKEEPING MACHINE Filed June 8, 1934 15 Sheets-Sheet 10 Oct. 17, 1939. H. NEuElTl-:R Er lu. 2,176,146

` BOOKKEEPING MACHINE Filed June 8, 1934 15 Sheets-Sheet 11 Fig, 16.

,In twI fa M 10o' $206 122 f# iw 4 E 1;; 29h 2526 Z\ /lz4z Z zio SEE a Y i Oct. 17, 1939. H. NEul-:n'x-:R er A1. 2,176,145

BOOKKEEPING MACHNE Filed June 8, 1934 15 Sheets-Sheet 12 Oct. 17, 1939. H. NEUEITER Er AL BOOKKEEPING MACHINE Filed June 8, 1954 15 Sheets-Sheet 13 F ig. .1d

Oct. 17, 1939. H. NEur-:ITER E1' A1.

BOOKKEEPING MACHINE Filed June 8, 1934 15 Sheets-Sheet 14 L: a www@ .www .nl

Oct. 17, 1939. H. NEuEm-:R Er AL BODKKEEPING MACHINE Filed June B, 1934 15 Sheets-Sheet 15 Snvent'ors Patented loot. 17, 1939 UNITED STATES PATENT OFFICE 2,176,148 BDOKKEEPING MACHINE Application June 8, In German =l1 Claims.

The present invention relates to bookkeeping and accounting machines, and is shown embodied in a machine used in banking houses for calculating and printing customers accounts when one or more deposits or withdrawals are made.

In the past it has been customary, when calculating such accounts, to enter the customers old balance in the machine, and to add or subtract 1! therefrom the deposits and withdrawls made. The new balance was then taken by a separate operation, to print the proper new balance on the customers account card or pass book, and to clear the balance totalizer for the next account. This 1-5 procedure necessitated one operation for the entry of the oid balance, one operation for each deposit or withdrawal, and a separate operation for taking the new balance. If it was further desired to accumulate these new balances for :zo future reference, it was necessary to operatethe machine through an additional adding cycle to reaccumulate such items. It will be noticed that such procedure requires, aside from the operations necessary for handling the deposits or with- 25 drawals, either 2 or 3 separate operations,

pending on whether it is desired to reaccumulate the new balances.

The present invention simplles the operation of the machine in respect to these 2 or 3 particu- 30 lar operations to the extent that the operator is required to start the machine only once to perform all oi them. With the structure herein show-n the operator rst enters the deposits and withdrawals on the balance totalizer, and then 35 sets up the old balance and starts the machine. This old balance is added or subtracted as the case may be with the deposits and withdrawals, after which the machine automatically takes the new balance and prints it on the customers ac- 40 count card or pass book, and reaccumulates this new balance in one of two separate totalizers according to whether such new balance is positive or negative.

With this and incidental objects in view, the invention includes certain novel features of construction and combinations of parts, the essential elements of which are set forth in appended claims and a preferred form or embodiment oi which is hereinafter described with reference to the drawings which accompany and form a part of this speciiication.

In the drawings:

Fig. 1 is a diagrammatic view oi the keyboard; 55 Fig. 2 is a iront sectional view of the structure 1934. Serial No. '129.712 y June 14, 1933 for shifting the balance totalizer for adding or subtracting;

Fig. 3 is a side view showing the rows of totallzers and the amount differential mechanism;

Figs. 4 and 5 are side sectional views of the 5 balance totalizerI Fig. 4 showing its connection with the dierential mechanism and Fig. 5 showing parts of the transfer mechanism;

Figs. 6 and 'I are side sectional views of the balance totalizer showing parts of the overdraft mechanism;

Figs. 8a and 8b are iront sectional views of the balance totalizer and show the connection between this totalizer and the overdraft mechanism; 15

Fig. 9 is a perspective view of the overdraft mechanism and its connection with balance totalizer and with the transaction key bank;

Figs. 10 and 11 are side views of the motor key bank, Fig. 10 showing its connection with the balance totaliaer, and with the motor clutch for starting the machine, and Fig. 11 showing its connection with parts oi.' the automatic cycle mechanism;

Fig. 12 is a side view of the transaction key 25 bank showing some of its connections with the automatic cycle mechanism and its connection with the overdraft mechanism;

Fig. 13 is a side view showing in detail some of the parts shown in Fis. 12; 30

Fig. 14 is a side view oi transaction key bank taken from the direction opposite to that of Fig.

12, and showing other connections between the keys oi this bank and the automatic cycle mecha-I nism: 35

Fig. 15 is a perspective View showing the transaction and motor key banks togetherwith many of the connections between these keys and the interior parts of the machine;

Figs. 16, 1'1 and 18 are iront views, Figs. 1'1 and 40 18 showing many parts in section; and

Figs. 19a and 19h show the timing of some oi the main parts of the machine.

Fig. 20 is a front elevation with the cabinet broken away to show parts oi the totalizer selecting mechanism.

Fig. 21 is a plan view of parts shown in Fig. 20.

GENERAL Dsscamroiv 'I'he present mechanism discloses a machine 50 having one adding and subtracting, or old balance totalizer oi a customary type embodying reversely rotated wheels. There is also provided adding totalizers to accumulate separately the. deposits. withdrawals, positive old balances, negative old 'motor bar.

balances, positive new balances, and negative new balances, and there is further provided two rows of special totalizers for additional classifications of any required nature.

When a deposit or withdrawal is to be made the proper transaction key D or W is depressed, and the machine operated by depression o! the This enters the amount on the proper side of the balance totalizer, and enters it in the special totalizer assigned to the transaction key depressed. The customer's old balance is next entered in the machine by depression oi the proper one of the transaction keys P-OB or N-OB, according to the algebraic character of the old balance. Upon depression of the motor bar the machine enters the amount set up on the proper side of the balance totalizer and into the transaction totalizer for the particular transaction key depressed.

Depression of one of these old balance transaction keys also causes the positioning or certain parts in the machine to cause the taking of a new balance during an additional cycle automatically following the entry oi' the old balance. During the taking oi' the new balance the overdraft mechanism for the balance totalizer automatically causes the total taking mechanism to be aligned with the proper side of the balance totalizer, and causes the proper new balance transaction key to be depressed to accumulate this new balance in the proper new balance transaction totalizer.

At the end of this second cycle oi operation the machine is automatically brought to rest with the parts in position for entering deposits and withdrawals for the next account.

DETAILED DESCRIPTION Keyboard The keyboardior the present machine is shown diagrammatically in Fig. 1 and includes amount keys |59, two rows of special totalizer keys ISI and a row of transaction keys bearing appropriate legends. In this transaction bank the keys D and W represent deposits and withdrawals respectively, and the keys P-OB and N-OB represent positive old balances and negative old balances respectively. The two blind keys situated near the center oi' this bank represent the positive and negative new balances. A motor key 24 is situated to the right of the transaction bank andcooperates with two blind keys 2li and 22 used to shift the operating mechanism for the balance totalizer so that amounts may be entered thereon algebraically. A kind of operation lever |4| is provided to take the totals from the various totalizers in the transaction bank. and in the two banks of special totalizer keys. Three totalizer coupling levers |42 also are provided for use in taking totals in these banks. The function of these levers is to select a particular totalizer when it is desired that the total be taken therefrom. The present invention, however, is not involved with the details of the taking of totals from any of the totalizers in these three rows so that the operation of these levers is not given. The special totalizer keys l5! in the two left hand rows control only their respective totalizers, while the transaction keys in the right hand row control not only the respective totalizer assigned to each, but further control the operation of the balance totalizer.

It must be remembered that the kind of operation lever |4| is used in taking totals from the totalizers for the three rows of totalizer selecting keys. but is not used when a total (new balance) is takenirom the balance totalizer. for such oper# ations are performed with the lever |4| in its addition position.

Dierential mechanism The differential mechanism is shown in a general way in Figs. 3 and 14, Fig. 3 showing the amount diierental, and Fig. 14 a few parts of the transaction differential. Referring to Fig. 3, the differential includes two complementarily movable arms |41 and |44 brought together through the action of planetary gears to adjust a minimum movement segment |45 under the inner end of a depressed amount key |50. These parts are actuated by a suitable pinion secured to a shaft |46 oscillated during each operation of the machine. The detailed movement of these parts is not given since they are fully shown and described in the U. S. Patent No. 1,792,569 issued to Ernst Breitling on February 11, 1931. It might be noted, however, that the particular form of planet gearing shown in Fig. 3 is not present in the patent, but is shown in a later patent disclosing the mechanism for taking totals in this type of machine. This later patent is numbered 1,899,455, issued to Ernst Breitling on February 28, 1933. For an understanding of the present case it is sufiicient to say that the movement oi the complementarily movable members |43 and |44 causes a movement oi' a large gear |51 to an extent commensurate with the value of the depressed amount key lill. The positioning of the minimum movement segment |45 causes a positioning of its corresponding amount type Wheel through a train of gears |41, |49, |52, |54, |65 and |56, and the rack |51; the gear |41 being driven by the segment |46, through beveled teeth appearing on both members.

'I'he differential mechanism for the transaction banks is partially shown in Fig. 14, and includes complementarily movable members itt and |01 and a minimum movement segment |05. As is customary in the art the differential mechanism for these banks controls the relative positioning o! the various totalizers, and the actuating mechanism so that an amount set up on the keyboard will be entered in the appropriate totalizer under control of the totalizer selecting keys. However, since the details of this selecting mechanism are not necessary to an understanding of the present invention they are not shown.

Totalizers The machine on which the present invention is shown includes three rows ofi interspersed totalizers (Fig. 3) situated radially about a central shaft |46. For identification these rows are numbered I, II and IlI. Each of these rows customarily contains nine totalizers. In the present instance two of the rows contain nine totalizers assigned to the two rows of special totalizer keys, and the third row contains six totalizers assigned to the transaction keys. I'he construction of these interspersed totalizer units and the operation thereof is generally well known in the art, and a form corresponding very closely to that used in the present mechanism is shown and described in U. S. Patent 1,896,936. issued to Bornkessel et. al. on February '1, 1933. The details of this mechanism, however, are not necessary to an understanding of the present invention so they are not shown.

'I'here is also provided a balance totalizer consisting of only one totalizer unit but having two rcverseiy rotating wheels in each decimal order. This totalizer unit is numbered IV in Fig. 3 and is better shown in Figs. 4, 5 and 8a and b. It includes two reversely actuated wheels 51 and 59 (Fig. 8a), a pair of which is provided for each decimal order. The operation of these wheels is briefly as follows:

The differential rotation of large gear |51 {Figs 3 and 4), commensurate with the value of the numeral key depressed in that particular decimal order, is transmittedA directly to pinion |53 (Fig. 4), and from there to pinion |59. Since, at the time of this operation pinion 56 is engaged with pinion |56, the motion Will be transmitted to the former and to a sleeve |53 (Fig. 8a) secured to this pinion. A rider |66 is loosely mounted on shaft |36, and is siidable longitudinally of the sleeve |53 as clearly shown in this figure. The rider has an upwardly extending prong protruding through a longitudinal slot in the sleeve |53, and is adapted to be moved longitudinally into the plane of either of the totalizer wheels 51 or 59 by longitudinal movement o shaft |36. When the rider is so moved it is in a position (See Fig. 5) to rotate one of the totalizer Wheels upon rotation of the pinion 56 and the sleeve |53.

The reverse rotation of Wheels 51 and 59 is made possible by the gear 5| on the shaft |38 (Fig. 5), and gears 52 and 54 (Fig. 8a) connected by a sleeve 53. When a rotation is imparted to the wheel 59, the movement is transmitted through a sleeve 53 and a gear wheel 43 to the wheel 54, sleeve 53, gear 52 and then to gear 5|. Rotation of the gear 5I causes rotation of a gear 48 attached to a sleeve 55 on which the totalizer wheel 51 is mounted. It will be noted that gear 5| is sufliciently broad as to mesh with gear 52 and also with gear 43.

Each of the totalizer wheels 51 and 59 carries a tooth |39 (Fig. 5), sufficiently long as to strike a finger |32 depending from an assembly of parts |33 appearing directly over the totallzer wheels in Figs. 5 and 8a. The long tooth of an actuated totalizer wheel displaces its finger |32 whenever it is moved through zero. This movement of the ngers |32 is for the purpose of transferring units from one order to another, and is assisted in this action by disks |6| and |62, and the mutilated gears |36 and |31 appearing in Fig. 5. However, since the details oi this mechanism are not necessary to an understanding of the present invention they are not given.

It will be noted, however, that the ringer |32 (Fig. 8), cooperating with the totalizer wheels 51 and 59 of the highest decimal order, is pinned to the shaft |34 so as to impart a slight rotation thereto whenever the wheels of highest order pass through zero.

overdraft mechanism.

The machine on which the present invention is shown includes a device commonly known as an automatic overdraft mechanism. This mechanism causes the totalizer to add a unit in the lowest decimal order whenever the totalizer wheel of highest order passes from zero to 9 or from 9 to zero to correct the inaccuracy appearlng in totalizers of this type whenever they are carried through zero to a negative quantity or returned through zero to a positive quantity.

The mechanism also includes the additional feature of allowing this additional or fugitive unit to be added in the units order, only when an actual overdraft occurs, and not when the totalizer passes from 9 to zero by exceeding its capacity in a positive direction, or from 6 to 9 by its capacity in a negative direction.

This mechanism is illustrated in Figs. 6, '7, 8 and 9. Referring to Fig. 9, it is seen that whenever either of the totalizer wheels 51 or 59 in the highest decimal order passes through zero they strike the finger |32 pinned to the shaft |34, and impart `to this shaft a counterclockwise rotation. A sleeve member |63 is situated on the right hand end o shaft |34, and is connected thereto by a pin and slot connection (see also Fig. 8b). This allows the shaft |34 to be shifted axially without a corresponding movement of the sleeve |63, but causes the sleeve to receive whatever rotation is imparted to the shaft. This sleeve is connected4 to a gear |64 by a spring |65, the spring being secured to both of these members, and suiiiclently strong that a partial rotation of sleeve |63 will be imparted bodily to gear |64 if the latter is free to rotate. The gear |64 is loosely mounted on shaft |34, and has a shoulder |66 lying in the vertical plane of a shoulder |61 on the sleeve |63. As shown clearly in Figs. 6 and 8b, these two shoulders normally lie some distance apart. With this construction when the linger |32 (Fig. 9) is given a rotation by one of the totalizer wheels 51 or 59, a correspending rotation is imparted to the sleeve |63, which, through spring |65, will rotate gear |64, if the same is not positively held against rotation. If it is so held the spring |65 wiil be tensioned and upon passage of the long tooth |39 out of the path of the iinger |32, the shaft |34 will spring back to its original position, relieving the tension in the spring. A segment |68 (Figs. 6 and 9) is loosely mounted on a shaft |69 and carries a stud |12 having pivoted thereon a dog |13. A sleeve member |15 is also loosely mounted on shaft |69 and carries a four tooth restraining wheel |16, four radial teeth |16, and a mutilated gear |86. The four tooth restraining wheel |16 lies in the vertical plane of the dog |13, which dog is constantly held against the wheel by the tension of a spring |14 secured to the dog and to a projection on the left side of the segment. The four teeth |16 are disposed around the sleeve |15 equidistantly and lie in two different planes. As shown in Fig. 9, these teeth lie alternately in the two planes. An arm |8| is secured to shaft |36 (Figs. '1 and 9) and lies in the plane of two of the teeth |16, when the balance totalizer is set for addition, and in the plane of the other two teeth when the totalizer is set for subtraction. The operation of these parts is briefly as follows:

When an overdraft appears in the register the shaft |34 is rotated counter-clockwise causing a counter-clockwise rotation of gear |64 and a clockwise rotation of segment |68, as well s s the wheel |16, teeth |16, and gear |86 through the operation of dog |13 by the gear |68. If the balance totalizer was in a positive condition at the beginning of this operation the arm |8| will be iying out of the plane of the tooth |16 situated closest to it at this time. Therefore the segment |63 will be free to rotate, upon rotation of the shaft |34. This causes a rotation of the sleeve |82 (Fig. 8b) as well as the transfer eccentric |83, to enter the fugitive unit in the lowest decimal order. The precise manner that this unit is entered is not necessary to an understanding of the present invention and will, therefore, not be described. Upon the return of shaft |34 to normal position, by parts of the transfer mechanism fini! in the highest decimal order, the segment and dog |18 will return to their original position. the dog |18 ratcheting over one of the teeth |10 to allow the wheels |10 and |80 and the teeth |18 to remain in their moved positions. This places one of the teeth |18 of the other plane in a position to have its movement restricted by the arm |8| unless the arm and shaft |30 are moved to their opposite lateral positions for the next operation involving a passage of the highest wheel through zero.

During the normal operation of the machine. when the balance totalizer is in a. positive condition and is overdrafted to a negative condition, the arm |8| will not prevent the entry of the fugitive unit. Likewise when the totalizer is in a negative condition and is returned through zero to its positive condition, the arm |8| will not prevent the entry of the fugitive unit, since the four teeth |18 are rotated 90 by each overdraft passage of the totalizer through zero. Thus. as long as the operation oi' the machine involves transactions causing the balance totalizer to pass through zero positively and negatively in alternate succession the arm |8| will have no restraining action at any time, the totalizer being positioned alternately in its adding and subtracting positions during these operations involving the overdraft. However, should the totalizer have its capacity exceeded in either direction, the arm |8| will be effective to restrain the entry of the fugitive unit by lying in the path of a tooth |18 and thereby causing gear |64 to be held against rotation until the long tooth |38 passes the finger |32 and the spring |85 rotates shaft |34 and nger |82 to normal position.

The operation of this overdraft mechanism is given only in a general way singe a very similar structure is fully shown and described in the above mentioned patent to Bornkessel et. al. See particularly Figures 16 to 21 of this patent.

overdraft control of totaliaer selection Fig. 9 also discloses mechanism for causing the overdraft mechanism to automatically select either of two totalizer selecting keys for depression. The mechanism operates in such a manner that whenever the totalizer is in a positive condition one of the two totalizer selecting keys is selected, and whenever the totalizer is in a negative condition the other totalizer selecting key is selected. In the present instance the keys selected are the blind positive and negative new balance keys situated in the transaction bank and used to select either of the two new balance totalizers for separately accumulating positive and negative new balances.

As above described whenever the balance totalizer passes from positive to negative or vice versa, the gear |80 receives a 90 rotation. By means of the mutilated construction of this wheel |88 (Figs. 'T and 9), a 90 rotation thereof will cause a 60 rotation of a wheel |84 and a disk |85 connected thereto by a sleeve |86, the parts |84 to |88 being loosely journaled on shaft |81. A triangular cam groove |88 is cut in the disk |85, and is so situated that it moves a roller |88 in one direction or the other during each 60 rotation. 'I'hese movements oi' the roller |88, it will be observed, are alternate, so that each time the gear |84 is given a movement, the roller |88 will be moved in a direction opposite to its last movement. The roller |88 is situated on the upper end of a bell crank |80 connected by a link |8| to a lever |82, connected by a sleeve |88 to an arm |84 having pivoted thereto a vertical link |85. It is now obvious that 60 rotations of gear |84 will move link |85 upward or downward depending upon its previous movement. The link |85 is connected to a lever |88 (see also Fig. 12) Divoted on stud |81 and connected to a detent slide 81. The lever |88, together with an arm |88 support the detent slide 81 for movement in the key bank. Two slotted levers 88 and 88 are pivoted to the slide 81 and are tensioned for outward movement by a spring |88 connected to each. These levers 88 and 88 have slots adapted to embrace studs |00 and |0| on the blind new balance keys, and are restrained in their outward movementby the studs |00 and |0|. Each of the levers 88 and 88 has a long prong adapted to cooperate with a stud 88 (Fig. 12) on the upper arm of a bell crank 84 pivoted on the stud 85. Each lever also has a short prong adapted to contact studs |00 and |0| when the levers lie in a position where their long prongs cooperate with the stud 88. By this arrangement of parts it is evident that when the link |85 is in its upper position the detent 81 will lie in its lower position where the long prong on lever 88 will contact the stud 88, and the short prong will contact the stud |00 so that upon clockwise rotation of the bell crank 84 the blind positive new balance key will be depressed, and when the link |85 is moved to its lower position by the balance totalizer being overdrafted, the slide 81 will be raised to its upper position where the long prong on the lever 88 will contact the stud 88. and the short prong will contact the stud |0I, so that upon clockwise movement of the bell crank 84 the blind negative new balance key will be depressed.

Totalizer selection for interspersed adding totalizers 'I'he various interspersed totalizers situated in rows I, II, and III (Fig. 3) are selected for operation by the three rows o! totalizer selecting keys shown in Fig. 1, as is customary n key set machines of this general character. The differential mechanism situated in these key banks (Figs. i4 and shifts mechanism in the totalizer assemblies so that when the totalizer shafts are moved to engage the totalizers for actuation the desired totalizer in each row will be coupled with the actuating mechanism. The segment |05 that is differentially positioned under the end of a depressed totalizer selecting key corresponds to the segment 41 in the above mentioned Breitling Patent 1,792,- 569 and is connected by a short sleeve 308 to a segment 280 meshing with a pinion 28| secured to a short sleeve 282. A segment 283 also is secured to the sleeve 282 and meshes with a pinion 284 secured to a drum 285 rotatably mounted on shaft 34. As shown in Fig. 20, this drum carries a helical groove in its surface, in which rests a roller 288 mounted on a bent arm 281 secured to a plate 300 by a sleeve 288. As better shown in Fig. 21, the plate 300 embraces restricted portions in shafts |30 and 305 so that movement of the plate 300 to the right or left will impart a corresponding movement to these shafts. Shaft |30 is grooved to accommodate riders |60 that connect the actuating wheels 50 with the totalizer wheels 58, and shaft 805 carries a longitudinal groove 308 (see also Fig. 3) and notches 301, one for each decimal order, which constitute an aligning means so that only the totalizer wheel aligned with rider |80 will be free to rotate with the actuating wheel 50.

By the above mechanism, when the segment |05 is adjusted by operation of the differential mech- -ated on either side of the motor key.

anism, as fully described in the Breitling Patent 1,792,569, the segments 290 and 293 are correspondingly adjusted and rotate drum 295. Such rotation adjusts plate 30 bodily to the right or left, causing a corresponding adjustment of the shafts |30 and 305. In this manner the various totalizers are adjusted under control of the depressed totalizer selecting keys.

Selection of the proper side of the balance totaltzer for adding and for taking the new balance This mechanism is disclosed in Figs. 2, 10, 11, 14 and 15. As heretofore mentioned the six keys in the transaction bank control the selection of the positive and negative sides of the balance totalizer. This control is exercised through the provision of a detent slide (Figs. 14 and l5) pivoted on two arms for movement in the key bank in the customary manner. This slide |0 has six cam portions, three of which cooperate with the deposit, positive new balance and positive old balance keys to select the positive side of the balance totalizer, and three cams cooperating with the withdrawal, negative new balance and negative old balance keys to select the subtracting side of the balance totalizer. The depression of any one of the first mentioned keys causes the slide I0 to be moved upward in the key bank, while depression of any one of the last mentioned keys causes the slide to be lowered. This raising or lowering causes a corresponding movement to be imparted to a link II pivoted to the slide I0 and to an arm I2 pivoted to the lower end of the link II. This causes movement of a lever I3 connected to lever I2 by a sleeve 20|, and movement of a link I4 connected to the lever I3, and further causes oscillation of a lever I connected to the link I4 and pivoted on a stud 203. Oscillation of the lever I5 causes an upward or downward movement of a slide I6 supported by the lever I5 and by an arm 202. Slide I6 has levers I1 and I8 pivoted thereon and pressed outwardly by the tension of a spring 205 connected to both. The levers I1 and I8 each have a long and a short prong, the long prongs being adapted to contact the under side of a stud 23 on the motor key 24, while the short prongs are adapted to contact studs I9 and 2| on blind keys 20 and 22 situ- It is apparent from an inspection of the drawings that when slide I6 is moved to its upward position by depression of one of the three keys for selecting the positive side ci' the balance totalizer, the short prong on the lower lever I1 wil engage the stud I9 on the lower blind key 20, and the long prong will engage the stud 23 on the motor key 24. Likewise when any one of the three keys for selecting the subtracting side of the totalizer is depressed the slide I6 will be lowered to the position shown in Fig. 1i and the upper lever I0 will contact the studs 2| and 23 for depressing the blind key 22.

A slide 206 (Figs. 10 and 15) is suspended on arms 201 and 200 for movement in the motor key bank. This slide 206 has two cams 209 and 2I0 situated under studs I9 and 2| on the blind keys in this bank. From an inspection of Fig. 10 it can be seen that when the blind key is depressed stud I9 will engage cam 209 and lower the slide 206, whereas when blind key 22 is depressed. stud 2| strikes cam 2I0 and raises slide 206. A pawl 2I| is pivoted at 2|2, and is held by a spring 2I3 in engagement with either of two notches in slide 206. This pawl is provided so that this slide 206 will be held in either of its positions until positively moved to the other position by depression of one of the blind keys. A segment 2 I4 (Fig. l0) is pivoted at 2 I5 to the key bank and carries a stud 2|6 lying within a slot in the slide 205. A segment 2I1 meshes with the segment 2|4 and is secured to another segment IIB lying adjacent thereto. Segment 2I0 meshes with a pinion 2I9 secured to a gear 220. By this train of connections movement of slide 206, causes a rotation of gear 220 and a pinion 22| (Fig. 2) meshed therewith and rotatable on shaft 60. Pinion 22| has bevel teeth 222 secured thereon and meshed with cooperating bevel teeth on a smaller pinion 223. This small pinion 223 is pivoted on a stud 224 secured to a sleeve 225 surrounding shaft 60. Another pinion 226 is loosely mounted on sleeve 225 and meshes with a segment 221 secured to a sleeve 220 having a tongue connection with a drum 229. The drum 229 is connected by a link 230 with the kind of operation lever |4| shown in Fig. 1. Since this lever |4| remains in its position shown during all the operations involved herein, the drum 229, sleeve 220, segment 221 and pinion 226 remain stationary at all times insofar as the description of the following operations are concerned.

Reverting now to the movement imparted to the pinion 22| by depression of one of the blind keys 20 or 22, it is seen that rotation of the pinion 22| causesrotation of the small pinion 223 and sleeve 225 in the same direction. This causes a corresponding rotation of a pinion 23| secured to the opposite end of the sleeve 225 and to a helical cam drum 232 having teeth meshing with pinion 23|. Rotation of this drum 232 causes a roller 233 lying within its groove to be shifted laterally. This roller is connected to an arm 234 'secured to shaft |40, so that rotation of the drum 232 by movement of the above described parts shifts the shaft |40 laterally. Shaft |40 is secured to a frame plate 235 carrying shafts |30 and |34, the lateral movement of which selects the adding or subtracting side of the balance totalizer, as clearly shown in Figs. 8a and 8b. From the above it is seen that a depression of the deposit, positive new balance or positive old balance keys followed by depression of the motor key causes the balance totalizer to be conditioned for adding, whereas a depression of the withdrawal, negative new balance or negative old balance keys followed by* depression of the motor bar causes the balance totalizer to be conditioned for subtracting.

Engaging and dsengagng of the interspersed adding totalizers The means to engage and disengage the three rows of adding interspersed totalizers shown in Fig. 3 involves mechanism to move the totalizer wheels toward the central shaft |46 by swinging the wheels about shafts 236 as a pivot. This mechanism includes a cam 304 (Fig. 20) secured to shaft 34 and cooperating with rollers 302 and 303 on an arm 30| secured to shaft 236. This shaft 236 is secured to the totalizer frame so that upon rotation of cam 304, the arm 30| and totalizer frame will oscillate about shaft 236 as a pivot. A side view of these parts is substantially the same as the showing of parts to 254 in Fig. 4. This oscillation of the totalizer frame causes the actuating gears 50 (Figs. 3 and 8a) to be engaged with intermediate gears 231 that are rotated diierentially, through gears 230, by the large differential gear |51 under control of a depressed amount key. During adding operations the totalizers are engaged for actuation just before the differential mechanism returns home 

